Horizontal boring, drilling, and milling machine



June 1, 1954 H. N. STEPHAN HORIZONTAL BORING, DRILLING, AND MILLING MACHINE Filed Jan. 25, 1951 7 Sheets-Sheet l INVENTOR- June 1, 1954 H. N. STEPHAN 2,679,678 HORIZONTAL BORING, DRILLING, AND MILLING MACHINE Filed Jan. 23, 1951 7 Sheets-Sheet 2 SPZZ Q 2 762 TABLE 0 (I INVENTOR. //fl4L/5 NSTEWAN Arraezve Y5 June 1, 1954 H. N. STEPHAN HORIZONTAL BORING, DRILLING, AND MILLING MACHINE Filed Jan. 25 1951 7 Sheets-Sheet 3 INVENTOR. Haas M STEPHAN m' gfi, a g [4; I I I W$ Arroelvsys June 1, 1954 H. N. STEPHAN HORIZONTAL BORING, DRILLING, AND MILLING MACHINE 7 Sheets-Sheet 4 Filed Jan. 23 1951 M STEP/MN W M INVENTOR.

Arraawvsys June 1, 1954 H. N. STEPHAN HORIZONTAL BORING, DRILLING, AND MILLING MACHINE Filed Jan. 25, 1951 7 Sheets-Sheet 5 JNVENTOR. 7 H4405 NSI'EP/IAN M, W$3M,

AITo /VEYS Patented June 1, 1954 HORIZONTAL BORING, DRILLING, AND MILLING MACHINE Hallis N. Stephan, Cleveland Heights, Ohio, as-

signor to The New Britain Machine Company, New Britain, Cnn., a corporation of Connecticut Application January 23, 1951, Serial No. 207,403

3 Claims. 1

The present invention relates to all types of combined boring, drilling and milling machines, including so-called horizontal boring machines, jigmills, jig borers, etc., and, more particularly, to the mechanism for controlling the movements of the various machine tool elements thereof.

The principal object of the invention is the provision of a novel and improved, combined boring, drilling and milling machine, including a single control member mounted for universal movement and capable of controlling the relative movement between two of the machine tool elements movable at right angles relative to each other in such a manner that the machine tool elements move relative to each other in the direction or approximate direction that the control member is moved.

The invention resides in certain constructions and combinations and arrangements of parts and further objects and advantages thereof will be apparent to those skilled in the art to which the invention relates from the fOllOWlllg description of the preferred embodiment described with reference to the accompanying drawings forming a part of this specification, in which similar reference characters designate corresponding parts, and in which Fig. 1 is a perspective view of a combined horizontal boring, drilling and milling machine embodying the present invention;

Fig. 2 is a diagrammatic view of that portion of the drive for the tool spindle which is located in the base of the machine;

Fig. 3 is a diagrammatic view of the portion of the drive for the tool spindle which is located in the spindle head;

Fig. 4 is a diagrammatic view showing the drive for reciprocating the saddle, table and spindle head;

Fig. 5 is an enlarged perspective View of the pendant control station;

Fig. 6 is an enlarged plan view, with portions broken away and in section, of the portable control station;

Fig, 7 is a sectional view approximately on the line l'! of Fig. 6; and

Figs. 8 and 9 are wiring diagrams of the electrical controls for the machine.

Referring to the drawings, the machine shown therein comprises a base A, provided at one end with a spindle head column B formed with vertical ways it and H upon which a spindle head C is mounted for vertical movement, and at the other end with a backrest or outboard support column D slidably supported on horizontal ways l2 and 13 formed on the upper side of the bed. The ways 12 and it also support a saddle E having transverse horizontal ways It and IE on the upper side which in turn support a work table F. The backrest column D is provided with ver-- tical ways upon which a backrest block G is mounted for vertical movement.

The spindle head is adapted to be moved vertically along the ways it and ill by a lead screw it rotatably supported in the machine in a suitable manner and having threaded engagement with a nut fixed in the spindle head. In addition to being rotatable in opposite directions, the tool spindle ii is movable in opposite directions longitudinally of its axis of rotation at different speeds to eifect both feed and rapid movements. The backrest block or outboard support G is movable simultaneously with the movement of the spindle head 0 by a vertical lead screw [8 located within the backrest column D and connected to the drive for rotating the screw [6. The saddle E is movable longitudinally of the tool spindle along the ways I 2 and i3 and the table F is movable transversely of the tool spindle along the ways i l and I5 at different speeds by mechanism hereinafter specifically referred to.

The speed and direction of rotation of the spindle, etc., and the aforesaid movements of the various machine tool elements, such as the feed and rapid movements of the spindle, head, saddle, table, etc., are performed by power and their operation may be controlled from any convenient place about the machine. The machine illustrated includes a reversible spindle drive motor 20 arranged for ceiling mounting and enclosed within the guard 2! adjacent to the lefthand end of the machine, a reversible feed motor 22 also located within the guard 2i, and a reversible spindle rapid traverse motor 23 mounted on the spindle head C. Other motors are employed but their location and operation are not necessary to an understanding of the present invention.

The spindle drive motor 2i! produces the spindle rotation and spindle feed movements. The feed motor 22 produces the feed and rapid movements of the spindle head C, saddle E and table F. The spindle rapid motor 23 produces the rapid movement of the spindle. The motors referred to are selectively connected to the various operating mechanisms through the medium of suitable speed change transmissions, clutches, etc., the controls for which are located on or adjacent to the base A of the machine,

spindle head C, pendant control station H fixed to the lower end of a tubular rod connected to a universally movable arm 24 by a flexible cable 25, and/ or a portable control station I connected to the free end of a flexible cable 25, the other end of which is plugged. into an outlet 2? in the base A of the machine.

The spindle ll is adapted to be rotated at various rates of speed by the spindle drive motor 2d through the medium of speed change gearing, designated generall by the reference character J, see Fig. 2, housed in a suitable gear box supported in the bed of the machine; a vertical shaft the lower end of which is rotatably supported in the gear box while the upper end is supported in the head column B; and back gears, designated generally by the reference character K located in the spindle head C. The motor 29 is connected to the driven shaft 30 of the speed change transmission J by a V-belt drive and spur gears 9i and 32, the former of which is fixed to a shaft carry" ing the driven pulley of the V-belt drive while t latter is fixed to the shaft 39. The driving shaft 33 of the transmission J is connected to the lower end of the vertical shaft 23 by miter gears. speed change transmission J provides nine differ ent speeds and comprises gear clusters 36 and 35 slidably supported on the shafts 39 and 33, respectively, and adapted to cooperate with gear clusters 36 and 3? fixed to an intermediate shaft 38.

The gear clusters 35 and 35 are adapted to ba shifted lengthwise of the shafts 39 and 39 upon which they are slidably splined to obtain the various speeds by any suitable mechanism. The par ticular mechanism employed forms no part of t present invention per se and is not illustrated and described herein in detail.

The driven shaft id of the back gears K is rotatably supported in the spindle head and is connected to the upper end of the vertical shaft 23 by a bevel gear 4! carried by the spindle head and splined to the shaft 28. The bevel gear 39 meshes with a bevel gear 62 fixed to the left hand end of the shaft 39. The spindle ii is slidably keyed within a spindle quill 43 rotata-bly supported by suitable bearings in the spindle head C, which spindle quill has a gear cluster comprising the gears M and Z5 fixed thereto. The gears a l and 45 are adapted to be selectively engaged by gears 45 and 47, respectively, of a gear cluster splined to the shaft 69. A high speed drive is obtainable through the medium of a V-belt final drive 48 when the gear 47 is shifted into engagement with a gear 59 fixed to a short shaft 59 journaled in the spindle head, which shaft carries the driving pulley of the V-belt drive 3. The gear cluster comprising the gears 49 and 4? is adapted to be shifted along the shaft 49 by a hand lever 52 fixed to the front end of a horizontal shaft journaled in the spindle head, the rear end of which shaft carries a yoke member engageable with the gear cluster.

The spindle l? is adapted to be fed or rapid traversed in either direction by a lead screw 53 rotatably supported in the spindle head extension and having threaded engagement with a twopiece nut 54 located within the feed slide 5-5 adjacent to the left-hand end of the spindle ii and connected thereto in a suitable manner. The lead screw 53 is adapted to be rotated in either direction and at different speeds from the spindle quill 53 through the medium of spur gears 56 and 57, the former of which is fixed to the left-hand end of the spindle quill while the latter is fixed to the right-hand end of a shaft 58 journaled in the spindle head and which forms the driving shaft of a feed speed change transmission, designated generally by the reference character L, housed within a suitable gear box in the spindle head. The gear 69 which forms the driving element of the feed change transmission L is operatively connected to a horizontal shaft 8| journaled in the spindle head through the medium of a gear 92 fixed to the left-hand end of the shaft El.

The shaft 6! is adapted to be operatively connected to a horizontal shaft 63 journaled in the spindle head and extending substantially the length thereof through the medium of gears 54 and 65 of a gear cluster fixed to the shaft 5 l. The gear 6 3 is in mesh with a gear 65 journaled on the shaft 63 and the gear 65 with a gear 6'! which in turn meshes with a gear 68 also journaled on the shaft 63. The gear 6! is journaled on a jack shaft 70 and the gear 68 rotates in a direction of rotation of the gear 85. The gears [iii and 68 are adapted to be selectively connected to the shaft 53 by a shiftable clutch element ii splined on the shaft 63 between the gears 66 and 5B, opposite ends of which clutch element are provided with clutch teeth adapted to cooperate with similar clutch teeth formed on the adjacent sides of the hub of the gears. The clutch element H is normally maintained in an intermediate or neutral position by a pair of springs '12 and '13 but is adapted to be shifted towards the left to drive the shaft 63 from the gear to or towards the right to connect the gear 68 with the shaft 63 by electric solenoids i l and 15, respectively.

The armature of the solenoid M is connected to a slidable member 15 provided with an inclined cam slot ll within which a roller carried by a 1ongitudinally slidable rod 18 engages. The armature of the solenoid 15 is connected to the bar 18 in a manner similar to that in which the armature of the solenoid i4 is connected thereto, except for the fact that the cam slot 89 in the memher 8! corresponding to the member I6 is inclined in the opposite direction to the slot 1?. The lower ends of the cam slots are widened so that the operation of one of the members 16 and BI will not be interfered with by the other. The slidable member 78 has a clutch yoke fixed to the righthand end thereof which engages in a groove formed in the shiftable clutch member H. The bar 78 is normally held in such a position that the clutch element H is in neutral position by the springs 12 and 13 which are located in a cut-out portion of the bar and engage opposite sides of a stationary stop fixed to the frame of the machine.

The left-hand end of the shaft 63 is connected to a gear 82 journaled thereon through the medium of an automatic release overload clutch 83. The gear 82 constitutes the driving gear of change gears, designated generally by the reference character M, the driven gear 8d of which is fixed to the end of the lead screw 53. Adjacent to its right-hand end, the shaft 63 is operatively connected to a spindle feed hand wheel 95, a crank 86 and fixed and adjustable dials, etc., as is known in the art. The mechanism shown per se forms no part of the present invention.

The spindle I? is adapted to be moved at a rapid rate in either direction by th reversible spindle rapid traverse motor 23 which is continuously connected to the shaft 63 by gears 90 and 9|, shaft 92, and bevel gears 93, 94, the latter of which is fixed to the shaft 63.

The reversible feed motor 22 is operatively 5 connected to a horizontally extending shaft H rotatably supported in the base A, through the medium of a Vbelt drive IN and spur gears 02 and I03. From the gear I03 the drive is either at a relatively slow or feeding rate through a variable feed change transmission, designated generally by the reference character N, and an overrunning clutch device, designated generally by the reference character 0, or at a relatively high or rapid rate through a normally disengaged disk clutch P, a shaft I04, and the overrunning clutch mechanism 0. The feed change gears, etc., are housed within a suitable gear box in the base A. Through the medium of the transmission N, the shaft I00 may be rotated at various speeds, and through the medium of the normally disengaged friction clutch P, the driven element of which is carried by a gear I continuously in mesh with the gear I02, the shaft I50 may be selectively rotated at a high rate of speed. The gear I03 is keyed to th driven shaft of the feed change transmission N and the gear I05 is journaled on the shaft I04. The driving element of the friction clutch P is splined to the shaft likl, which shaft is in axial alignment with the shaft I00, and is adapted to be actuated to engage the clutch P upon energization of an electricallyoperated solenoid I06 connected to one lever of a bell crank lever I0?! pivoted on the frame, the

other lever of which is connected to a member I00 which in turn actuates the clutch elements.

The last or driving gear I E0 of the transmission N is continuously in mesh with a gear I l I which forms the low speed element of the overrunning clutch mechanism 0. The gear III is rotatably supported on the shaft I00 and has formed integral therewith the driving element H3; of a normally engaged toothed clutch, the driven element I I3 of which is splined on the shaft M90. The left-hand end of the driven element H3, as viewed in Fig. l, has a plurality of sloping teeth or cam surfaces I l d which cooperate with similar teeth H5 on a high speed driving member H6 fixed to the right-hand end of the high speed shaft I04. The member I I 3 is continuously urged towards the left, as viewed in Fig. 4, by a compression spring Ill interposed therebetween and the gear II I. The construction is such that the shaft I00 is normally connected to the transmission N through the normally engaged clutch elements H2 and H3 and the gears H0 and III, with the shaft Ill l rotating at the same speed as the shaft I00 due to the engagement of the teeth H4 and H5.

Upon engagement of the friction clutch P, the shaft I 04 is rotated at a higher rate of speed than the shaft I00. This difference in speed causes the teeth [It of the slidable clutch element H3 to climb the teeth H5 of the element i I 6 carried by the shaft I00, with the result that the slidable clutch element I I3 is moved towards the right, disengaging the teeth thereof from the teeth of the clutch element II2, which in turn disengages the low speed drive. Thereafter, the shaft I00 rotates at th same high speed as the shaft I04. Movement of the member I I3 towards the right is limited by the compression spring 1, and the construction is such that the cooperating teeth H4 and H5 are never permitted to clear each other. Both sides of the teeth II and II 5 are inclined which makes the device 0perable for either direction of rotation of the motor 22. When the clutch P is released, the spring I I! reengages the cooperating clutch teeth of the clutch elements H2 and II3, and reconnects the feed to the shaft I00 in place of 'the' rapid traverse.

The shaft I00 is adapted to be operatively connected to a horizontal shaft I journaled in the base A of the machine and extending substantially the length thereof through the medium of gears I2I, I22 of a gear cluster fixed to the shaft I00. The gear I2I is in mesh with a gear I23 and the gear I22 with a gear I24, which latter gear is in turn in mesh with a gear I 25. The gear I20 is journaled on a jackshaft I26 and the gear I rotates in a direction opposite to the direction of rotation of the gear I23. The gears I23 and I25 are supported coaxially with the shaft I20 being keyed to driven elements of a double friction clutch S of commercial construction.

The particular clutch shown is a Maxitorq floating disk, self-locking, double clutch sold by The Carlyle Johnson Machine Company, Manchester, Connecticut, and is shown in Sweets File for Product Designers for 1944 and is not herein shown and described in detail. Suflice it to say that it comprises a shiftable sleeve member I2'I which when shifted to the right causes the shaft 20 to be driven by the gear I23 and when shifted to the left causes the shaft I20 to be driven by the gear I25. The clutch element I2? is provided with a groove within which an operating arm or yoke I20 engages. The arm I28 is fixed to the left-hand end of a slidable bar I30 which is nor mally maintained in position to hold the clutch element I2! in neutral by compression springs I35, E32 located in a cut-out portion of the bar I30 and abutting against opposite sides of the stationary stop fixed to the frame of th machine.

The bar I30 is adapted to be shifted toward the right to connect the gear I23 to the shaft I28 by an electric solenoid I 33 and toward the left toconnect the gear I25 to the shaft E20 by an electric solenoid H34. The armature of the solenoid its is connected to a slidable member I35 provided with an inclined cam slot 336 within which a roller carried by the slidable bar E30 engages.

The armature of the solenoid I3 is connected to v .the slidable bar I30 in a similar manner except for the fact that the cam slot I37 in the member I 38 corresponding to the member I35 is inclined in the opposite direction to the slot 530.

The upper ends of the cam slots E30, I3! are widened so that the operation of one of the members I 35, I30 will not be interfered with by the other. Opposite ends of the shaft E20 are operatively connected to the lead screws I6, I8 which raise and lower the spindle head and backrest block, respectively, by miter gear-g I40 and MI, I42 and I43, respectively. The gear I40 is fixed V to the left-hand end of the shaft I20 and is continuously in mesh with the gear I 4! which is keyed to the lower end of the lead screw 6. The gear I M is also engaged by a gear I44 fixed. to the rear end of a shaft 545 projecting to the front of the machine where it is arranged for the reception of a hand crank, thus providing for manual raising and lowering of the spindle head and backrest column block. The gear I42 is splined to the shaft I20 so as to permit movement of the backrest column D toward and from the spindle head column B.

The table F is reciprocated upon the ways I4 and I5 by a lead screw I rotatably supported in the saddle E and in engagement with a cooperatlug nut fixed to the underside of the table. The lead screw IE0 is connected to and driven by a splined shaft IEI extending lengthwise of the bed of the machine by gearing, designated generally;

by the reference character-Qthe particular construction of which gearing forms no part of the present invention. The shaftII is adapted to be connected to a short shaft I52 in a manner simi. lar to that in which the shaft I20 is connected to the shaft I00. Sufiice it to say that the duplicate parts are designated by the same reference characters with a prime mark affixed thereto. The shaft I52 is in turn operatively connected to the shaft I90 by gearing, designated generally as R.

The saddle E i moved along the ways I2, l3 by a'lead screw I53 supported in and extending lengthwise of the bed A and in enga gemcnt with a cooperating not carried by the saddle E. The lead screw I53 is connected to a shaft I54 by gearing, designated generally as S. The shaft I54 is connected to and driven from a shaft I55 in a-manner similar to that in which the shaft I29, which raises and lowers the spindle head C is connected to the shaft I09 and will not be described in detail. Sumce it to say that the duplicate parts are designated by the same reference characters with a double prime mark affixed thereto. The shaft I55 is connected to and driven by the shaft I09 by the gearing R.

In operation, after the desired spindle speeds and the desired feed rate; have been selected by the speed change transmission J and the feed change transmissions L and N, the remaining operations of the machine are controlled from the electrical control stations H and I. The feed push buttons for the spindle head C, saddle E and table F are arranged in groups and are ar ranged to give directional control. Each group has two continuous feed push buttons and two inch feed push buttons. The two continuous feed push buttons in each group are provided with electric light bulbs therein which illuminate the push buttons when they are momentarily depressed and remain lighted so long as the feed actuated thereby is in operation. This indicates at a glance to the operator which unit is being fed and in which direction. The controls are preferably o interlocked that the spindle head, saddle or table cannot be fed continuously unless the spindle I7 is rotating.

Rotation of the spindle I1 is controlled by three push button switches I50, I6I and I62. The two upper push button switches I69, It! cause the spindle to rotate continuously in opposite directions upon being instantaneously depressed. The right-hand push button I69, see Fig. 5, initiates continuous rotation of the spindle in a clockwise direction while the left-hand push button switch IBI initiates continuous rotation of the spindle in the opposite or counterclockwise direction. The lower jog push button switch I62 rotates the spindle in. a counterclockwise direction so long as the push button is depressed. The spindle is adapted to fed continuously toward the right by momentarily depressing the spindle continuous feed push button switch I63 and toward the left by momentarily depressing the spindle continuous feed push button switch I64. The spindle is moved at a rapid traverse rate toward the right or left upon either the spindle rapid right or spindle rapid left push button switches I55, I56 bein depressed. The movement continue only as long as the push button switches are held depressed.

The spindle head continuous feed and jog feed push button switches are designated by the referencecharacters I61, I68, III], III. Instantaneous actuation of the head continuous feed up push'button'switch I61 initiates continuous feed movement of the spindle head in an upward direction and actuation of the head continuous feed down push button switch I58 initiates movement of the spindle head in the opposite direction. The head jog push button switches IIO, I'Ii cause inch feed movement of the spindle head up and down, respectively. The table continuous feed and jog feed forward and back push button switches are designated by the reference characters I'I2, I13 and lid, I75, respectively. Instantaneous actuation of the table continuous feed forward push button switch I12 initiates continuous feed movement of the table toward the front and actuation of the table continuous feed back push button switch II3 initiates movement of the table toward the back of the machine. The push button switches I'I I, II5 cause inch feed movement of the table forward and back, respectively. The saddle continuous feed and jog push button switches are designated by the reference characters I'IG, I'll and I18, I79, respectively. Instantaneous actuation of the saddle continuous feed right push button switch I16 initiates continuous feed movement of the saddle toward the right and actuation of the saddle continuous feed left push button switch ITI initiates continuous feed movement of the saddle toward the rear. The push button switches I78, IIQ cause inch feed movement of the saddle toward the right and left, respectively. Rapid movement of the spindle head, saddle and table is controlled by a push button switch I80. When the push button switch I30 is depressed, any or all of the movements of the spindle head, saddle or table operating at that time are continued but at a rapid traverse rate so long as the push button switch I89 is held depressed. In addition to the push button switches mentioned above, the pendant control station H comprises a start feed motor push button switch I8I for the feed motor a stop all feeds push button switch I82 and a stop all switch I83. The latter switch stops all operations of the machine.

One of the objects of the present invention, previously referred to, is the provision of a novel and improved machine of the character herein shown and described comprising a single control element supported for universal angular movement and operative to control the feed movement of two machine tool elements reciprocable in directions at right angles to each other. In the embodiment of the invention shown, the single control element is the manually operable lever I90 projecting through an enlarged opening in the housing iQI of the movable control station I and operatively connected within the housing to a centrally located boss I92 projecting from the bottom of the housing by a universal joint I93. The lever I90 is normally maintained in an upright position; that is, normal to the side of the housing I9I through which it projects by four spring-pressed detents I9 1 equally spaced thereabout and engaging the underside of an annular member I95 carried by the lever I99. The portable control station I also comprises four double throw snap switches I95, I91, I98, I99 equally spaced about the member I95 and adapted to be actuated thereby when the normally operable lever I98 is moved out of its normal position.

In the embodiment shown, the vertical feed movement of the spindle head C and the forward and back horizontal feed movement of the table F may be controlled from the portable control station I and the switches I95, I97, I98, I99

:are connected in the control circuits which effect I the feed movements of these machine tool eleof any two or more of the movable machine tool.

elements could be controlled from the portable control station I. It is also to be understood that the control station I need not be portable but that it could be fixed to any desired part of the machine; for example, the spindle head C. Alternatively, the control station I could be incor porated in the pendant control station E.

Referring again to the embodiment shown, the switches I96, I91 are located on opposite sides of the operating lever I96 and contro1 the up and down movements of the spindle head C, re spectively. In a similar manner, the switches I98, I99 control forward and back movements of the table F. When the control lever I9!) is moved toward the indicia Head Up, the spindle head C is caused to i eed in an upward direction. Movement of the lever I90 in the opposite direction; that is, toward the Head Down indicia, causes the spindle head to be fed in a downward direction. Movement of the lever I90 to the right or left; that is, toward the Table Forward or Table Back indicia, causes the table F to feed forward or back, respectively. Two feed movements can be effected simultaneously by moving the control lever I93 to a position intermediate two of the indicia referred to, in which position it actuates the two adjacent switches. The construction is such that it is not necessary to return the control lever I90 to its normal or central position before being moved to efiect an additional or a different feed movement if the second or new feed movement position of the control lever I90 is adjacent to the first feed movement position.

Operation The operation of the machine will now be described with reference to the wiring diagram. Since the particular manner of controlling the spindle rotation and the feed and rapid traverse movements of the spindle in the spindle head forms no part of the present invention, this part of the control for the machine is not herein illustrated and described. Sufiice it to say that the various operations previously referred to can be effected by pressing the proper push button switches I30 to I63. The continuous movements, once initiated, can be stopped by pushing one or the other of the stop push button switches #82, I 83 as the circumstances require.

The feed motor 22 which supplies th power for feeding the spindle head C, saddle E and table F in the desired direction, commonly referred to as the milling feeds, normally operates continuously in the same direction and is started by momentarily depressing the start feed motor push button switch I8I. This establishes a circuit from the line L-! through the stop all push button switch I83, wire 299, stop all feeds push button switch I82, wire I, start feed motor push button switch I8I, wire 262, operating solenoid 253 of feed forward contactors 204 to L-Z.

Energization of the operating solenoid 203 of the feed forward contactor 2M closes the normally open contacts 2%, 206, 20?, 288 thereof. The closing of normally open contacts 295 establishes a holding circuit for the operating solenoid 283 after the start feed motor push button switch IBI is released. The closing of normally open contacts 2%, 201, 208 of feed forward contactors 204 connects the motor to the power lines L-I,

13-2 and L-3 and the motor thereafter rotates in the forward direction until either the stop all feeds push button switch I82 or stop all push button switch I83 is depressed or one of the overtravel limit switches, etc., not shown, is opened.

With the feed motor 22 operating, the pairs of gears I23, I25 and I23, I25 and 523" and I25" rotatably supported on shafts I26, I5I and I54, respectively, are driven with the gears of each pair rotating in opposite directions. As previously explained, these gears are adapted to be selectively connected to the shaft upon which they are supported and, in turn, feed the machine tool element moved thereby in the desired direction by the shiftable clutch elements IZ'I, I2? and I2? under the control of the clutch operating solenoids I33, I34 and I33, I34 and I33", I 34", respectively, the energization and deenergization of which solenoids are controlled from the pendant and portable control stations H and J, respectively.

Referring first to the control as it is effected from the pendant control station H as distinguished from the portable control station I, which will be referred to later, the spindle head C is caused to feed up continuously by momentarily depressing the head continuous feed up'push button switch I67, closing the normally open contacts thereof. This establishes a circuit from the line L-I through the stop all push button switch I33, wire 200, stop all feeds push button switch I82, wire RBI, normally open contacts of head continuous feed up push button switch I 67, which contacts are now closed, wire 2H1, operating solenoid 2 of head feed up control relay M2 to line 13-2 actuating relay 2H2, closing its normally open contacts 2l3, 2M. The closing of normally open contacts 2 I 3 establishes a hold ing circuit for the head continuous feed up con trol relay 2I2 from the wire 20! to the wire ZIIJ. The closing of the normally open contacts 2; of relay 2I2 establishes a circuit from the wire ZtlI through the contacts 2M, which are now closed, wire 2P5, operating solenoid 2H; of head feed up relay 2|! to the line L-2. Actuation of head feed up relay ZI'I closes the normally open contacts 2H3 thereof establishing a circuit from the line L-I through normally open contacts 2 I 8, which are now closed, wire 22!], and the head feed up solenoid I33 to line L-Z.

Energization of the head feed up solenoid I33 shifts the clutch element I21 into engagement with the clutch element on the hub of the gear I23 causing the shaft I23 to be rotated in a direction to raise the spindle head C at a feed rate. The head continues to feed up until the holding circuit for head feed up control relay ZIZ is broken by the operator depressing the stop all feeds push button switch I82 or the stop all push button switch I83 or upon the opening of an interlock or an overtravel limit switch, not shown. It is to be understood that suitable interlocks and overtravel limit switches are employed to prevent attempted actuation in two directions at one time, etc. as is customary in machines of this character. These controls, however, are omitted from the wiring diagram, etc. for purposes of simplicity.

The spindle head C is caused to feed down continuously by momentarily depressing the head continuous feed down push button switch I63 closing the normally open contacts thereof. This establishes a circuit from the line L-I through the stop all push button swich I33, wire 2%, stop all feeds push button switch, wire ZIII, normally open contacts of head continuous feed down push button switch I58, which contacts are now closed, wire 22I, operating solenoid 222 of head feed down control relay 223 to line L-Z, actuating relay 223, closing its normally open contacts 22 225. The closing of normally open contacts 224 establishes a holding circuit for the head continuous feed down control relay 223 from the wire ZilI to the wire 22L The closing of normally open contacts 225 of relay 223 establishes a circuit from the wire Elli through the contacts 225, which are now closed, wire 2%, operating solenoid 22! of head feed down relay 223 to the line L-2. Actuation of head feed down relay 223 closes the normally open contacts 239 thereof establishing a circuit from the line LI through normally open contacts 239, which are now closed, wire 23L and the head feed down solenoid I34 to L-2. Energization of the head feed down solenoid I3 5 shifts the clutch element I2! into engagement with the clutch element on the hub of the gear I25 causing the shaft I to be rotated in a direction to lower the spindle head C at a feed rate. The head continues to feed down until the holding circuit for head feed down control relay 223 is broken by the operator depressing the stop all feeds push button switch I82 or the stop all push button switch I83 or upon the actuation of an interlock, not shown.

With the continuous feed operating in either direction, the movement of the spindle head can be continued in whichever direction it is operating but at a rapid traverse rate by the operator depressing the rapid movement push button switch I50 to close the normally open contacts thereof. This establishes a circuit from the line L-I through the stop all push button switch I83, Wire 200, stop all feed push button switch I 82, wire Zili, normally open contacts of rapid movement push button switch 130, which are now closed, wire 232, operating solenoid 233 of rapid movement relay 234i to L-2 causing the relay to operate and close its normally open contacts 235. This establishes a circuit from the line L-I through normally open contacts 235, which are now closed, wire 236, and operating solenoid 06 for clutch P to energizing operating solenoid I06 engaging the clutch P, causing operation of the high speed. shaft IM which drives the shaft H38 and in turn the lead screw I6 at a rapid traverse rate in a manner previously described.

The spindle head C may be jog fed in an upward direction by depressing the head jog feed up push button. switch I'lfi to close the normally open contacts thereof, which contacts are in parallel circuit with the normally open contacts 2M of head continuous feed up control relay 2 I 2. When push button switch Ill} is depressed to close its contacts, a circuit is established from the wire ZGI through the normally open contacts of head jog feed up push button switch IEB, wire 2I5 and operating solenoid 2H3 of head feed up relay ZI'I to line L-2. The actuation of head feed up relay 2I'I closes the normally open contacts 2H3 energizing the head feed up solenoid I33 in a manner previously described, thus shifting the clutch element 2? into engagement with the clutch element on the hub of the gear I causing the shaft :20 to rotate and the head C to feed in an upward direction. The up movement of the head continues so long as the head jog feed up push button switch lid is held depressed.

The spindle head C may be jog fed in a down direction by depressing the head jog feed down push button switch Ill to close the normally open contacts thereof, which contacts are in parallel circuit with the normally open contacts 225 of head continuous feed down control relay 223. When push button switch I'll is depressed to close its contacts, a circuit is established from the wire 2%! through the normally open contacts of head jog feed down push button switch Ill, wire 226 and operating solenoid 22? of head feed down relay 228. The actuation of head feed down relay 223 closes the normally open contacts 230 energizing the head feed down solenoid 134 in a manner previously described, thus shifting the clutch element I27 into engagement with the clutch element on the hub of the gear I25 causing the shaft I20 to rotate and the head C to feed in a downward direction. The down movement of the head continues so long as the head jog feed down push button switch I "ii is held depressed.

Continuous feed of the table F in a forward direction is initiated by momentarily depressing the table continuous feed forward push button switch I12, closing the normally open contacts theerof. This establishes a circuit from the line L-I through the stop all push button switch I83, wire 2G0, stop all feeds push button switch I82, wire Ziil, normally open contacts of table continuous feed forward push button switch H2, which contacts are now closed. wire 2-31, operating solenoid 233 of table feed forward control relay 2% to line L-Z actuating relay 24B, closing its normally open contacts 24!, 262. The closing of normally open contacts 2M establishes a holding circuit for the table continuous feed forward control relay 2 18 from the wire 2M to the wire 231. The closing of the normally open contacts 242 of relay 249 establishes a circuit from the wire 20! through the contacts 2 32, which are now closed, Wire 2553, operating solenoid 2% of table feed forward relay 245 to the line L-Z. Actuation of table feed forward relay 2 l5 closes the normally open contacts 24% thereof establishing a circuit from the line L-I through normall open contacts 246, which are now closed, wire 2:27, the table feed forward solenoid I33 to L-2. Energization of the table feed forward solenoid I33 shifts the clutch element i2? into engagement with the clutch element on the hub of the gear I23 causing the shaft l5! to be rotated in a direction to move the table F forward. The table continues to feed forward until the holding circuit for table feed forward control relay 2 30 is broken by the operator depressing the stop all feeds push button switch I82 or the stop all push button switch I83 or upon the opening of an interlock, not shown.

The table F is caused to feed back continuously by momentarily depressing the table continuous feed back push button switch H8 closing the normally open contacts thereof. This establishes a circuit from the line L-i through the stop all push button switch I83, wire 269, stop all feeds push button switch I82, wire 29!, normally open contacts of table continuous feed back push button switch I'IS, which contacts are now closed, wire 2%, operating solenoid 2553 of table feed back control relay 25! to line L-2, actuating relay 25L closing its normally open contacts 252, 253. The closing of normally open contacts 7252 establishes a holding circuit for the table continuous feed back control relay 25! from the wire Bi l to the wire 248. The closing of normally open contacts 253 of relay 25E establishes a circuit from the wire 281 through the contacts 253, which are now closed, wire 254, operating solenoid 255 of table feed back relay 256 to the line L-2. Actuation of table feed back relay 2% closes the normally open contacts 251 thereof establishing a circuit from the line L-I through normally open contacts 251, which are now closed, wire 258, the table feed back solenoid 53 to L-2. Energization of the table feed back solenoid 134 shifts the clutch eiemc-nt 62? into engagement with the clutch element on the hub of the gear I25 causing the shaft I5I to be rotated in a direction to move the table back at a feed rate. The table continues to feed back until the holding circuit for table feed back control relay is broken by the operator depressing the stop all feeds push button switch I82 or the stop all push button switch IE3 or upon the actuation of an interlock, not shown.

With the continuous feed operating in either direction, the movement of the table can be continued in whichever direction it is operating but at a rapid traverse rate by the operator depressing the rapid movement push button switch I80 to close the normally open contacts thereof. This energizes the operating solenoid IElE and engages the clutch P in a manner previously described.

The table may be jog fed in a forward direction by depressing the table jog feed forward push button switch I14 to close the normally open contacts thereof, which contacts are in parallel circuit with the normally open contacts 242 of table continuous feed forward control relay 24ft When push button switch lid is depressed to close its contacts, a circuit is established from the wire 20! through the normally open contacts of table jog feed forward push button switch I M, wire 243 and operating solenoid 2 .51 of table feed forward relay 2% to line L-2. The actuation of table feed forward relay 245 closes the normally open contacts are energizing the table feed forward solenoid I33 in a manner previously described, thus shifting the clutch element 521' into engagement with the clutch element on the hub of the gear l23 causing the shaft i-5I to rotate and the table F to feed in a forward direction. The forward movement of the table continues so long as the table jog feed forward push button switch 114 is held depressed.

The table may be jogged in a back direction by depressing the table jog feed back push button switch I15 to close the normally open contacts thereof, which contacts are in parallel circuit with the normally open contacts 253 of table continuous feed back control relay 25L When push button switch H5 is depressed to close its contacts, a circuit is established from the wire 2o: through the normally open contacts of table jog feed back push button switch H5, wire 25% and operating solenoid 255 of table feed back relay 253. The actuation of table feed back relay 255 closes the normally open contacts 251 energizing the table feed back solenoid I34 in a manner previously described, thus shifting the clutch element 521' into engagement with th clutch element on the hub of the gear 125' causing the shaft 15! to rotate and the table F to feed in a backward direction. The back movement of the table continues so long as the table jog feed back push button switch W5 is held depressed.

Continuous feed of the saddle E toward the right is initiated by momentarily depressing the saddle continuous feed right push button switch I16, closing the normally open contacts thereof. This establishes a circuit from the line L-I through the stop all push button switch I83, Wire 200, stop all feeds push button switch I82, wire 20I, normally open contacts of saddle continuous feed right push button switch I16, which contacts are now closed, wire 250, operating solenoid 2M of saddle feed right control relay 262 to line L-2 actuating relay 262, closing its normally open contacts 263, 264. The closing of normally open contacts 263 establishes a holding circuit for the saddle continuous feed right control relay 262 from the wire 20I to the wire 260. The closing of the normally open contacts 264 of relay 2S2 establishes a circuit from the wire 2M through the contacts 264, which are now closed, wire 265, operating solenoid 266 of saddle feed right relay 261 to the line L-2. Actuation of saddle feed right relay 261 closes the normally open contacts 268 thereof establishing a circuit from the line L-I through normally open contacts 258, which are now closed, wire 21!), and the saddle feed right solenoid I33" to L2 Energization of the saddle feed right solenoid I33" shifts the clutch element I21" into engagement with the clutch element on the hub of the gear I23" causing the shaft I 5 to be rotated in a direction to move the saddle E toward the right. The saddle continues to feed right until the holding circuit for saddle feed right control relay 262 is broken by the operator depressing the stop all feeds push button switch I82 or the stop all push button switch I83 or upon the opening of an interlock, not shown.

The saddle E is caused to feed left continuously by momentarily depressing the saddle continuous feed left push button switch IT! closing the normally open contacts thereof. This establishes a circuit from the line L-I through the stop all push button switch I83, wire 200, stop all feeds push button switch I82, wire 20!, normally open contacts of saddle continuous feed left push button switch I11, which contacts are now closed, wire 2', operating solenoid 212 of saddle feed left control relay 213 to line L2, actuating relay 213, closing its normally open contacts 214, 215. The closing of normally open contacts 214 establishes a holding circuit for the saddle continuous feed left control relay 213 from the wire ZIiI to the wire 21!. The closing of normally open contacts 215 of relay 2'53 establishes a circuit from the wire 20I through the contacts 215, which are now closed, wire 215, operating solenoid 21? of saddle left relay 218 to the line L-2. Actuation of saddle feed left relay 218 closes the normally open contacts 230 thereof establishing a circuit from the line L-I through normally open contacts 288, which are now closed, wire MI, and the saddle feed left solenoid I34 to L-2. Energization of the saddle feed left solenoid I34 shifts the clutch element E21" into engagement with the clutch element on the hub of the gear I25 causing the shaft ltd to be rotated in a direction to move the saddle toward the left at a feed rate. The saddle continues to feed left until the holding circuit for saddle feed left control relay 213 is broken by the operator depressing the stop all feeds push button switch IE2 or the stop all push button switch I83 or upon the actuation of an interlock, not shown.

With the continuous feed operating in either direction, the movement of the saddle can be continued in whichever direction it is operating but at a rapid traverse rate by the operator decreasing the rapid movement push button switch if; I99 to close the normally open contacts thereof and engage the clutch P.

The saddle may be jog fed in a right-hand direction by depressing the saddle jog feed right push button switch I19 to close the normally open contacts thereof, which contacts are in parallel circuit with the normally open contacts of saddle continuous feed right control relay 292. When push button switch I19 is depressed to close its contacts, a circuit is established from the wire 29I through the normally open contacts of saddle jog feed right push button switch I19, wire 265 and operating solenoid 296 of saddle feed right relay 267 to line L4. The actuation of saddle feed right relay 26l closes the normally open contacts 269 energizing the saddle feed right solenoid I33" in a manner previously described, thus shifting the clutch element I21 into engagement with the clutch element on the hub of the gear I29" causing the shaft I54 to rotate and the saddle E to feed towards the right. The movement of the saddle toward the right continues so long as the saddle jog feed right push button switch I18 is held depressed.

The saddle may be jogged in a left direction by depressing the saddle jog feed left push button switch I I9 to close the normally open contacts thereof, which contacts are in parallel circuit with the normally open contacts 2'55 of saddle continuous feed left control relay 273. When push button switch I19 is depressed to close its contacts, it establishes a circuit from the wire 29! through the normally open contacts of saddle jog feed left push button switch H9, wire 216 and operating solenoid 2?! of saddle feed left relay 279 to line L-2. The actuation of saddle feed left relay 219 closes the normally open contacts 289 energizing the saddle feed left solenoid I39" in a manner previously described, thus shifting the clutch element IZ'I" into engagement with the clutch element on the hub of the gear I causing the shaft I54 to rotate and the saddle E to feed in a left-hand direction. The left-hand movement of the saddle continues so long as the saddle jog feed left push button switch H9 is held depressed to energize the operating solenoid I96 to engage the clutch P in the manner previously described. The rapid traverse movement continues so long as the rapid movement push button switch I89 is depressed.

The switches I99, I93, I93 and I99 which are located in the portable control station I have both normally open and normally closed contacts but the normally closed contacts which are interlock contacts will be disregarded. Suffice it to say that the normally open contacts are in parallel circuit with the corresponding jog feed push button switch for the same machine tool element and the interlock or normally closed contacts which open upon the closing of the normally open contacts interrupt or stop the corresponding continuous feed if it happens to be operating at the time the control lever I99 is moved to close the normally open contacts.

Referring to the wiring diagram, the head up switch 96 is in parallel circuit with the head jog feed up push button switch I19 across the wires 29! and 2I5 and upon the closing thereof by manipulation of the control lever I99 by the operator a circuit is established from the line L-I through the stop all push button switch i933, wire 299, stop all feeds push button switch I82, wire 129i, switch I99, which is now closed, wire 2 I5, operating solenoid 2 I9 of head feed up relay 2i"! to line L-2. The actuation of head feed up relay Zll closes the normally open contacts 2I8 energizing the head feed up solenoid I33 in a manner previously described, thus shifting the clutch element i??? into engagement with the clutch element on the hub of the gear I23 causing the shaft I29 to rotate and the head C to feed in an upward direction. The up movement of the head continues so long as the head feed up switch is held depressed.

The head may be moved down by manipulating the control lever I99 to close head down switch i9l. This switch is in parallel circuit with the normally open contacts of head jog feed clown push button switch Ill and when closed establishes a circuit from the wire 219i through head down switch I97, wire 229 and operating solenoid 22'? of head feed down relay The actuation of head feed down relay 229 closes the normally open contacts 299 energizing the head feed down I solenoid I39 in a manner previously described,

thus shifting the clutch element 52'! into engagement with the clutch element on the hub of the gear I25 causing the shaft I29 to rotate and the head C to feed in a downward direction. The down movement of the head continues so long as the head down switch i9? is held closed.

The table may be moved in a forward direction by moving the control lever I99 to a position to close the table forward switch I99, which switch is in parallel circuit with the table jog feed forward push button switch I98. When the table forward switch I98 is closed, it establishes a circuit from the wire 129! through its normally open contacts, which are now closed, wire 243 and operating solenoid 24 3 of table feed forward relay 295 to line L-2. The actuation of table feed forward relay 2 15 closes the normally open contacts 249 energizing the table feed forward solenoid I35 in a manner previously described, thus shifting the clutch element I2? into engagement with the clutch element on the hub of the gear :23 causing the shaft I5! to rotate and the table F to feed in a forward direction. The forward movement of the table continues so long as the table forward switch I99 is held closed.

The table may be moved in a back direction by moving the control lever I99 in a direction to close the table back switch I99, which switch is in parallel circuit with the table jog feed back push button switch H5. When the switch I99 is closed, it establishes a circuit from the wire 29I through table back switch I99, wire 254 and operating solenoid 255 of table feed back relay 256. The actuation of table feed back relay 259 closes the normally open contacts 25? energizing the table feed back solenoid I39 in a manner previously described, thus shifting the clutch element I21 into engagement with the clutch element on the hub of the gear I 25 causing the shaft I5! to rotate and the table F to move in a backward direction. The back movement of the table continues so long as the table back switch I99 is held closed.

From the foregoing it will be apparent that the objects of the invention heretofore enumerated and others have been accomplished and that there has been provided novel and improved machine tool and particularly a combined boring, drilling and milling machine having two machine tool elements movable relative to each other in directions at right angles and a single control member mounted for universal movement about an axis and capable of controlling the relative movement between the two machine elements such that the machine tool 17 elements move relative to each other in the direction or the approximate direction that the control member is moved.

While the preferred embodiment of the invention has been described with considerable detail, the invention is not limited to the particular construction shown and it is my intention to cover hereby all adaptations, modifications and uses thereof which come within the practice of those skilled in the art to which the invention relates and the scope of the appended claims.

Having thus described my inventicn, I claim:

1. In a machine tool having a plurality of separably movable machine tool elements and power actuators for moving said machine tool elements in opposite directions indivi ually of each other, a portable control station'including a portable housing, a manually operable control member supported in said housing of said portable control station for universal movement in two directions, means for biasing said manually operable control member to a central position, a plurality of electric switches for selectively controlling the operation of said power actuators to selectively move said machine tool elements in selected directions, means for connecting said last-named plurality of electric switches in said housing of said portable control station concentrically of said manually operable control member for selective actuation by movement of said control member, and a flexible electric cable interconnecting said last-named plurality of electric switches and said power actuators.

2. In a machine tool having a plurality of separably movable machine tool elements and power actuators for reciprocating said machine tool elements in opposite directions individually along linear paths at right angles to each other, a pendant control station, a plurality of manually operable electric switches on said pendant control station for selectively controlling the operation of said power actuators to selectively move said machine tool elements in selected directions, and a portable control station including a portable housing, a manually operable control member supported in said housing of said portable control station for universal movement in two directions, means for biasing said manually operable control member to a central position, a plurality of electric switches for controlling the operation of said power actuators to selectively move said machine tool elements in selected directions, means for connecting said last-named plurality of electric switches in said housing of said portable control station concentrically of said manually operable control member for selective actuation upon movement of said control member, and a flexible electric cable interconnecting said last-named plurality of electric switches and said power actuators.

3. In a combined horizontal boring, drilling and milling machine of the character described having bed provided with a vertical column adjacent to one end, a member slidably supported on said bed, a second member slidably supported on said first member, a third member slidably supported for vertical movement along said vertical column, a spindle rotatably supported in said third member and a plurality of power actuators for independently reciprocating a plurality of said members in opposite directions at right angles to each other, a pendant control station, a plurality of manually operable electric switches on said pendant control station for selectively controlling the operation of said power actuators to selectively move said members in, selected directions, a portable control station including a portable housing, a manually operable control member supported in said housing of said portable control station for universal movement in two directions, means for biasing said manually operable control member to a central position, a plurality of electric switches for controlling the operation of said power actuators to selectively move said members in selected directions, means for connecting said last-named plurality of electric switches in said housing of said portable control station concentrically of said manually operable control member for selective actuation upon movement of said control member, and a flexible electric cable interconnecting said last-named plurality of electric switches and said power actuators.

References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,840,853 Shaw et al. Jan. 12, 1932 2,251,015 Gallimore July 29, 1941 2,350,174 Lucas et al. May 30, 1944 

